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Genomics-driven exploitation of aphid-killing bacteria as a source of novel biopesticides

Principal Supervisor: Dr. Matthew JennerLink opens in a new window (Warwick)

Co-supervisor: Prof. Robert Jackson (Birmingham), Dr. Lijiang Song (Warwick)

PhD project title: Genomics-driven exploitation of aphid-killing bacteria as a source of novel biopesticides

University of Registration: University of Warwick

Project outline:

Aphids are major insect pests of agriculture and horticulture, causing damage to many economically important crop plants through direct feeding and/or as efficient vectors of numerous plant viruses. At present, aphid control measures are limited and rely heavily on insecticides such as carbamates, pyrethroids, neonicotinoids, tetramic acids, and chordotonal organ modulators such as flonicamid/pymetrozine. The target for many of these chemicals is the insect central nervous system, however, insects can rapidly evolve resistance to insecticides thus rendering these chemicals ineffective. There is therefore an urgent need to develop alternative and more sustainable means of aphid control.

Recent studies have shown that environmental microbes have varying abilities to kill insects. On this basis, screening of >140 different plant-associated bacteria through aphid ingestion assays identified multiple bacteria that could kill aphids, with nine strains of different genera showing potent aphid-killing ability. One bacterium in particular (PpR24), a member of the Pseudomonas fluorescens species complex, was observed to grow inside aphids, and is capable of killing insecticide-resistant aphid clones. Furthermore, when sprayed onto plants, PpR24 can reduce aphid infestation. RNA-sequencing and genetic manipulation of PpR24 has demonstrated that it uses a range of toxins to kill the aphid. Together, these findings indicate great promise for the use of this bacterium, and others, as biocontrol agents to control aphid infestation of crop plants. Building on this concept, a recent genome analysis of one of the other nine strains (P. fluorescens PfR37) identified a biosynthetic gene cluster (BGC) that may produce a pyrrolizidine alkaloid-like molecule. This class of molecules are usually produced by plants as a defence mechanism against insect herbivores but has recently been discovered to be produced by bacteria.

This project aims to apply a genomics-driven chemical ecology approach to understand the molecular details of the aphid-microbe interaction. Initially, a broad screen of environmental bacteria will be conducted to identify novel aphid-killing strains. These will be prioritised on the basis of aphid-killing ability and subjected to complete genome sequencing to identify the biosynthetic potential of each bacterium. Prioritised strains will be cultured in the laboratory to induce specialised metabolite production and screened using liquid chromatography-high resolution mass spectrometry (LC-HRMS) to identify metabolites of interest and linked to BGCs via gene knock-out experiments. Metabolites will be purified using preparative-high performance liquid chromatography (HPLC) and chemical structures will be determined using NMR spectroscopy. A combination of crude extracts and purified metabolites will be tested for their toxicity towards aphids using an established assay, with the ultimate aim of identifying novel aphid-killing agents.


This project will be hosted in Dr. Matthew Jenner’s Lab at the University of Warwick, and conducted in close collaboration with Prof. Robert Jackson (University of Birmingham, Secondary PI) where initial bacterial screening and aphid-killing experiments will be carried out. All other aspects of the project will be conducted in the Jenner Lab.


BBSRC Strategic Research Priority:

Understanding the rules of life Plant Science, and Microbiology, Renewable Resources and Clean Growth - Industrial Biotechnology, and Bio-energy, and Sustainable Agriculture and Food - Microbial Food and Safety, and Plant and Crop Science.

Techniques that will be undertaken during the project:

  • Genomics and Bioinformatics
  • Microbiology and Cell Culture
  • Molecular Cloning and Genetic Engineering
  • Metabolite Screening (LC-HRMS)
  • Metabolite Purification (HPLC)
  • Chemical Structure Elucidation (NMR) 

Contact: Dr Matthew Jenner